Broadband log periodic antenna with phase reversing parasitic elements



Sept. 22, 1970 N, B ARBANQ ETAL 3,530,484

BROADBAND LOG PERIODIC ANTENNA WITH PHASE REVERSING PARASITIC ELEMENTS Filed May 6, 19,68 6 Sheets-Sheet 1 1- NORMAND BARBANO x HOWARD HOCHMAN ATTORNEY Sept. 22, 1970 BARBANO ETAL 3,530,484

BROADBAND LOG PERIODIC ANTENNA WITH PHASE REVERSING PARASITIC ELEMENTS Filed'May 6, 1968 6 Sheets-Sheet 2 flu fi 4 ATTORNEY Sept. 22, 1970 N. BARBANO ET AL BROADBAND LOG PERIODIC ANTENNA WITH PHASE REVERSING PARASITIC ELEMENTS Filed May 6, 1968 llb 6 Sheets-Sheet 5 INVENTORS NOR MAND BARBANO HOWARD HOCHMAN M igw/z q ATTORNEY Se t. 22, 1970 N. BARBANO ET AL 3,530,484

BROADBAND LOG PERIODIC ANTENNA WITH PHASE REVERSING PARASITIC ELEMENTS 6 Sheets-Sheet 4 Filed May 6, 1968 INVENTORS NORMAND BARBANO HOWARD HOCHMAN BY L ATTORNEY V llb Sept. 22, 1970 BARBANO ET AL 3,530,484

BROADBAND LOU PERIODIC ANTENNA WITH PHASE REVERSING PARASITIC ELEMENTS Filed May 6, 1968 6 Sheets-Sheet 5 INVENTORS NORMAND BARBANO HOWARD HOCH MAN ATTORNEY Sept. 22, 1970 BARBANO ET AL 3,530,484

BROADBAND LOG PERIODIC ANTENNA WITH PHASE REVERSING PARASITIC ELEMENTS Filed May 6, 1968 6 Sheets-Sheet G I NYE NTORS NORMAND BARBANO HOWARD HOCHMAN BY} ATTORNEY United States Patent 3,53%,434 Patented Sept. 22, 1970 ABSTRACT OF THE DISCLOSURE This television antenna comprises three log periodic arrays mounted on one boom in end-to-end relation for receiving television and FM broadcast frequencies in three separate bands. All of the elements in the three arrays lie in the plane of the boom. Each of the two higher frequency arrays comprises a series of log periodic Yagi-Uda cells with each parasitic element functioning as a director for one cell and a reflector for the adjacent cell. The axial locations of the parasitic elements are adjusted to match the impedance of dipoles to the feed line and are independent of the logic periodic dimensions and spacings of the dipoles. Double parasitic elements are located adjacent to the driven elements in the high VHF band to provide a smooth transition in frequency response between adjacent driven elements and insure substantially uniform antenna patterns over the band.

The single boom or longitudinal support for the active and parasitic elements is a hollow split tube, preferably rectangular in cross section, comprised of juxtaposed electrically conductive substantially identical channel members mechanically secured to each other in relation by insulators. These members also constitute balanced feed lines for the antenna elements, being electrically connected at one end to the inner and outer conductors, respectively, of a coaxial insulated cable which extends within the members from the opposite end.

BACKGROUND OF THE INVENTION This invention relates to antennas, and in particular to an extremely high performance antenna for domestic reception of television and FM signals.

One of the difficult problems in the design of domestic television antennas is the relatively large span of frequencies they must received. Presently the range extends from 54 mHz. (channel 2) to 890 mHz. (channel 80). Since performance characteristics including gain and front to back ratio are strictly related to the electrical length of the antenna, attempts to limit the overall physical length to a practicable dimension, such as the customary to 16 feet, have resulted in compromises which degrade efficient reception of signals.

A typical compromise adopted by many manufacturers of commercial television antennas is to superimpose elements in one frequency band on elements of another by stacking, telescoping or interspersing the respective elements. For example, the UHF elements may be mounted between VHF elements on the same length of the boom. Not only have such antennas had limited success in achieving electrical efficiency required for high quality reception of signals but they have also necessitated mechanically complex feeding and supporting structures which increase the fabrication cost and complicate installation procedures.

In addition to electrical performance, domestic television antennas should be sufficiently simple in design to permit installation by the do-it-yourself home owner as well as to facilitate handling and shipping. The structure should be lightweight and capable of being readily assembled by the amateur and professional installer alike. Moreover, the position of prominence that a television antenna occupies on the home or other dwelling dictates an aesthetic standard which frequently is not met by antenna structures with superimposed elements or stacked arrays.

SUMMARY OF THE INVENTION An exceptionally high performance television antenna is provided by constructing the high VHF and UHF sections as a plurality of Yagi-Uda cells in longitudinal series having log periodically related driven elements and interspersed parasitic elements. The parasitic elements are nonlinearly or non-logarithmically spaced from the active elements and each parasitic functions as a director and as a reflector for adjacent cells. This arrangement of elements permits reduction of the physical length of these antenna sections without corresponding reduction of the electrical length while maintaining an optimum impedance match between the driven elements and the feed line. Accordingly the antenna gain and front to back ratio, which are directly related to electrical length of the antenna, are relatively high while VSWR is minimum and reception patterns substantially uniform over all bands.

The hollow boom which supports the antenna elements is also a two-conductor transmission line having a characteristic impedance when loaded that is substantially the same as the characteristic impedance of the coaxial line which feeds it. Symmetrical spacing of the twin boom members improves impedance matching of the line to antenna elements.

A general object is the provision of a high performance television antenna having a mechanically simple lightweight structure that is economical to produce and convenient to ship and assemble.

A further object is the provision of a broadband log periodic array With parasitic elements interpersed between driven elements in a manner to improve the match of impedance of all dipoles to the feed line.

Another object is the provision of such an array with an improved arrangement of parasitic elements for insuring a uniform antenna response pattern over the VHF band.

A further object is the provision of a television antenna with a combination boom and feed line assembly for supporting and feeding all receiving elements in the VHF- UFH-FM bands in the plane of the boom.

DESCRIPTION OF DRAWINGS FIG. 1 is a plan view of the complete television antenna embodying this invention;

FIG. 2 is a schematic view in perspective showing the relative positions of the antenna elements and the transmission line which feeds them;

FIG. 3 is a fragmented plan view of a simplified form of antenna embodying the invention;

FIG. 4 is an elevation of the antenna of FIG. 3 as viewed on line 44 of FIG. 3;

FIG. 5 is a transverse section taken on line 5-5 of FIG. 3;

FIG. 6 is a schematic view in perspective of the conibination boom and twin transmission line which supports and energizes the elements of the antenna;

FIGS. 7 and 8 are transverse sections taken on lines 7-7 and 88, respectively, of FIG. 6;

FIG. 9 is an enlarged perspective view of the front or high frequency end portion of the antenna showing the electrical connections at the feed point;

FIG. 10 is a transverse section taken on line 1010 of FIG. 9;

FIG. 11 is a section taken on line 11-11 of FIG. 10;

FIG. 12 is a perspective view of the central portion of the antenna showing the connection of the front and rear boom portions at which the twist in the twoconductor transmission line occurs; and,

FIGS. 13 and 14 are transverse sections taken on lines 13-13 and 1414, respectively, of FIG. 12.

DESCRIPTION OF PREFERRED EMBODIMENTS An embodiment of the invention is shown in FIG. 1 as an antenna 10 having a boom 11 extending along the axis of the antenna and supporting a plurality of axially spaced transversely extending parallel elements 12 from the 10 wfrequency end 13 to the high frequency end 14 of the antenna. A bracket 15 mounted on the central part of boom 11 provides a mechanical connection to the mast, not shown. A coaxial cable 16 extends from the low frequency end of boom 11 for connection to external circuits such as a television receiver R. The antenna preferably is constructed to receive signals in the broadcast television and frequency modulation (FM) bands which are divided into three groups:

Group A: low VHF and FM54 to 108 mHz. Group B. high VHF-474 to 216 mHz. Group C: UHF470 to 890 mHz.

The antenna 10, for purposes of this description, is divided into sections, A, B and C as shown to indicate the frequency separated portions of the antenna which receive signals in the above identified frequency groups A, B and C, respectively. The lengths and spacings of the elements in antenna section A vary in accordance with a logarithmically periodic constant '1- in a manner well known in the art and therefore this aspect of the design of section A does not constitute part of this invention. Elements 12 in sections B and C, however, comprise a succession or series of cells of a Yagi-Uda array, each complete cell including a driven element, a reflector and a director. The size and spacings of the elements of the cells are related to each other in a manner described below to achieve the required electrical length for maximum gain, front to back ratio and pattern uniformity without superposition of these cells and within the size limitations established by custom and installation standards for television antennas.

Referring now to FIGS. 2, 3, 4 and 5, the elements of antenna sections A, B and C are energized by transmission lines 11a and 11b which, in practice, comprise the boom 1 and extend from one end of the antenna to the other. Feed line 11a is electrically connected to or may constitute the outer conductor 38 of coaxial cable 16 and feed line 11b is an electrical extension of the inner conductor 37. This general technique of feeding the balanced transmission line of a multi-element array with an unbalanced line is described in Pat. No. 3,155,976, assigned to the assignee of this invention.

As shown in FIG. 2, section A of the antenna comprises a plurality of parallel dipoles 18 connected to feed lines 11a and 11b which are stacked in a plane perpendicular to the dipoles, i.e., vertically stacked and spaced one above the other as shown in the drawing. The elements of dipoles 18 on the same side of the antenna axis X are successively connected alternately to feed lines 11a and 11b. Antenna sections B and C, however, are fed by lines 11a and 11b positioned in a plane parallel to the antenna elements, i.e., the horizontal plane as shown. The transition of the feed lines from a vertical plane in section A to a horizontal plane in section B occurs at point 20 where the relative position of the lines is rotated or twisted through a quarter of a turn while maintaining an appropriate interline spacing.

Section B of the antenna comprises dipoles 2226, inclusive, see FIG. 1, which are directly connected to feed lines 11:: and 11]) such that the dipole elements on one side of the antenna are electrically connected to one feed line and the remaining dipole elements on the opposite side are connected to the other feed line. Thus, elements 22' and 22 comprising dipole 22 are electrically connected to feed lines 11a and 1112, respectively. The dimensions, i.e., lengths, and spacings of successive dipoles in section B as well as in sections A and C decrease in the direction toward feed point 14 in progressive increments of a predetermined ratio characteristic of the log periodic relationship.

In order to reverse the phase of currents in the feed lines 11a and 11b between adjacent dipoles in section B as required for an end fire array, parastitic elements 27-30, inclusive, are interspersed between adjacent dipoles, respectively, and are closely coupled to though insulated from feed lines 11a and 11b. This principle of phase reversal using parasitic elements between dipoles is more fully described in Pat. No. 3,286,268, assigned to an assignee of this invention. Briefly, the parasitic element receives energy in combination with the adjacent driven element, becomes resonant at a frequency corresponding to its dimensions, and simultaneously introduces a phase reversal of the energy in the feed line. Thus, the parasitic element not only reverses the phase of the signal between adjacent driven elements but also acts as an active receiving element itself.

In the course of developing and testing the television antenna, and in particular that portion adapted to receive signals in the high VHF band, i.e. section B, discontinuities and general degradation in the antenna reception patterns were observed to occur at frequencies between the resonant frequencies of adjacent dipoles. This is believed to have been produced by the sharp resonant characteristic (high Q) of the interspersed parasitic elements, resulting in a narrow band peaking of the frequency response between the adjacent driven elements and ultimate breakup of the pattern at these points. Purtherrnore, this undesirable resonance effect of the parasitic elements becomes more pronounced'as the antenna length is decreased. In accordance with the invention, this problem is solved by substitution of a parasitic doublet for each single parasitic element at which the pattern breakup occurs. Each parasitic. doublet comprises two parasitic elements on opposite sides of the plane containing the adjacent dipoles and equally spaced from that plane and from the nearest dipole. In the preferred embodiment of the antenna, parasitic doublets 27, 28 and 29 are provided in section B, the elements of each doublet being designated the prime and double prime of the corresponding reference character. The effect of each doublet is to lower the Q of the parasitic and thus broaden its frequency response so that no pattern breakup occurs and a uniform signal reception is assured. Insulators 31 sepa rate the individual parasitic elements from the feed lines.

Section C of the antenna comprises dipoles or driven elements 32 and parasitic elements 33 interspersed between the dipoles in the manner described above for section B. However, because of the relatively closer spacing of the driven and parasitic elements in section C, the

resonance effect of the single parasitic element does not significantly perturb the reception pattern and therefore the parasitic doublet is not used. In the embodiment shown in FIG. 1, parasitic element 33' which functions as a reflector for the low frequency dipole 32' in section C is physically disposed within section B, to the right of dipole 26 as viewed.

The relative lengths and spacings of the driven elements 22-26, inclusive, in section B vary in a log periodic manner along the axis X of the antenna. Thus, the ratio of the spacing S between dipoles 22 and 23 to the length L of dipole 22 is 1 T L 2 tan (oz/2) where -1- is a constant and a is the angle of convergence of lines connecting extremities of the dipoles. The relative spacings of axially successive parasitic elements or doublets from the adjacent dipoles, however, are not constant but vary in a non-linear or non-log periodic manner. In particular, the ratio of the spacing S between parasitic element 29 and driven element 24 to the spacing S between element 24 and adjacent parasitic element 28 is not equal to the ratio of spacing S between elements 30 and 25 to spacing 8,, between elements 25 and 29. This may be expressed as where p is a constant. This non-linear spacing is likewise applicable to the parasitic elements 33 and adjacent dipoles 32 in section C of this antenna.

'In one embodiment of the invention which was act-ually built and tested, the ratio p for section B of the antenna increased from the low frequency to high frequency ends of the section, i.e., from element 22 to element 26.

Thus

For section C of this antenna, the ratio p increased from low frequency end of the section to the middle portion and decreased from the middle portion to the high frequency end of the section.

Stated differently, if S equals the axial spacing between a driven element and the parasitic element on the low frequency side of the driven element and equals wavelength at which the driven element is resonant (i.e., twice the dipole length), then the ratio of S /x diminishes in a direction from the low to high frequency ends of section B. For antenna section C, this ratio decreases in a direction from the low frequency end toward the middle of that section and then increases toward the high frequency end of the section. These changes or nonlinear variations in spacing between driven elements and adjacent parasitic elements are illustrated in FIG. 1 by curves 34 and 35 for antenna sections B and C, respectively.

Sections B and C of the antenna consist essentially of a plurality of axially adjacent Yagi-Uda cells B1 to B5, inclusive, and C1 to C8, inclusive. Each cell comprises a driven element, a reflector consisting of the parasitic element on the low frequency side of the driven element, and a director consisting of a parasitic element on the high frequency side of the driven element. In section C the length of each reflector is equal to the length of the driven element with which it is associated. In section B the length of each reflector is related to the length of the driven element by the geometric factor l Each parasitic element functions both as a reflector and as director for the driven elements, respectively, on either side of it. The lengths and spacings between adjacent driven elements are logarithmically related to each other, i.e., by the geometric ratio 1- described above, thereby enabling the series of Yagi-Uda cells to have an significantly broadband response.

The improved performance of the antenna, resulting from the above described variations in spacings of driven and parasitic elements for successive cells in sections B and C is believed to be attributable to the compensating effect such non-linear spacing has on the impedance mismatch between driven element and feed line caused by the somewhat abrupt terminating or truncating of the antenna sections. More than one cell of the antenna section are active at one time during normal reception of signals in one broadcast channel for that section. More cells therefore are available to receive signals in the central portion of the section than at its ends. As a consequence, the mutual loading effect of the elements varies with longitudinal position, resulting in a corresponding variation in the effective impedance of the elements. Such impedance mismatch is corrected or compensated by change of the impedance affecting relationship of driven and parasitic elements in successive cells, preferably by variation of the spacing between these elements. Other compensation techniques may be employed, however, such as change of the diameters of the dipole and/ or parasitic element or lengths of the dipole and/or parasitic element. The simplest and most economical technique, however, is adjustment of the parasitic-dipole spacing. By so improving the match of the dipole impedance to the line, the dipole becomes a more effective receiving element which in turn improves the efficiency of reception of the parasitics. While this improvement in performance has been realized by practice of the invention in a three section television antenna, the concept may also be used with utility and advantage with other log periodic antennas having interspersed parasitic elements, for example, the antenna described in Pat. No. 3,286,268.

The combination boom and feed line assembly 11 comprises substantially identical channel members 11a and 11b, see FIGS. 6, 7 and 8, for the front or higher frequency part of the antenna and channel members 11'a and 11'b, identical relative to each other but not to members 11a and 11b, for the back or lower frequency portion. These front and back portions of the feed lines are joined or connected at transition point 20 described in detail below. Coaxial cable 16 extends within the channel members for the entire length of the boom and has its center conductor 37 connected at the high frequency end 14 to feed line 11b and its outer conductor 38 connected to the adjacent end of feed line 11a. This connection of coaxial cable 16 to feed lines 11a and 11b therefore constitutes the feed point of the antenna. Coaxial cable 16 preferably has an external covering 39 of insulation, see FIGS. 11, 13 and 14, which protects it from damage.

Channel members 11a and 11b preferably are substantially identical in size and shape and are symmetrically disposed about the longitudinal axis of the boom. Each channel member has a pair of parallel side walls 40, see FIGS. 9 and 10, connected by an integral end wall 41. The lateral spacing 42 of adjacent side walls 40 of the channels is uniform but this spacing for the back portion of the boom preferably is larger than for the front. In order to electrically connect the coaxial cable 16 to members 11a and 11b, a conductive clamp 45, see FIGS. 9, l0 and 11, is secured to the interior of channel 11a by screws 46 and circumferentially grips outer conductor 38. An L- shaped conductive block 47 secured by screws 48 to the inside of channel member 11b opposite clamp 45 has a transversely extending leg 49 to which the forwardly projecting inner conductor 37 of the coaxial cable is connected. Thus, channel member 11b is essentially an electrical extension of the center conductor of the coaxial cable. The two channel members are mechanically integrated into a rigid antenna boom by interconnection through a series of longitudinally spaced insulators 51 and 52, see FIGS. 9 and 10, which are fastened to the upper and lower Walls 40 of the two channel members by screws 53 and 54, respectively.

The dipole and parasitic elements preferably are made from diameter aluminum tubing. In order that dipoles for sections B and C may be securely though removably mounted on the sides of channel members 11a and 11b, threaded studs 56 are permanently secured to and project outwardly from walls 41 of the channel members and one end of each dipole tube is tapped for threaded engagement with the stud. The parasitic element in antenna sections B and C are also releasably mounted on the channel members by spring clips 58 fastened to insulators 51 and 52 in a manner to electrically isolate the parasitics from the channel members. If desired, removable top caps, not shown, may be used to lock the spring clips for more secure retention of the parasitic elements. Conductive spring clips 58' of this type are also used to directly electrically connect dipoles 18 in section A to the channel members, respectively.

In order to change the position of the boom channel members from a laterally spaced relationship in sections B and C of the antenna to a vertically spaced relationship in section A, the transition assembly see FIG. 12, is employed. This assembly provides the required twist in the feed lines while maintaining a high degree of mechanical rigidity in the entire boom. Assembly 20' comprises electrically conductive angle-shaped straps 60 and 61 on diagonally opposite corners of the boom and similarly shaped insulating straps 62 and 63 made of high strength dielectric, such as fiberglass, on the other two corners of the boom. These straps are tightly secured by screws 64 as shown to front channel members 11a and 11b and to rear channel members ll'a and 11b and essentially mechanically and electrically bridge the longitudinal gap 65 between the front and back portions of the boom. The length of gap 65 is selected to conform to the characteristic impedance of the line. Longitudinally spaced insulators, one of which is shown at 66 in FIG. 12, maintain constant the vertical spacing 42 between back channel members 11'a and 11'b. The dipoles on opposite ends of the transition assembly are balanced with respect to each other. To this end dipole element 18 in section A and dipole element 22' in section B, both connected to the same feed line (11a, 11a), extend in opposite directions from the boom. Similarly, elements 18" and '22" extend oppositely from the same feed line (11'b, 11b) at the ends of assembly 20'.

An important feature of the above described feed line structure is the resultant balanced loading of the line by the dipoles and parasitics connected to it. In section A, the spacings 42 between identical channel members 11a and 11b are symmetrical about the horizontal plane containing the boom axis and have negligible loading effect on the dipoles 18 connected to the top and bottom of the boom. Similarly, the spacings 42 between identical channel members 11a and 11b of the front boom portion are symmetrical about the vertical plane containing the boom axis and so have no adverse effect on either the dipoles or the parasitic elements of antenna sections B and C because of the balanced relation of these parts.

The physical length of the entire array described above has been maintained within a practicable limit while retaining the simplicty of a substantally mono-plane array and without superimposing the antenna sections for different bands upon one another. The separate sections of our antenna are axially spaced from each other; for example, the high frequency dipole 26 of section B is axially spaced from the low frequency dipole 32 of adjacent section C. By so separating the individual antenna sections from each other, interaction between the sections is minimized and substantial improvement in gain, front to back ratio, VSWR and pattern uniformity is achieved.

The combnation boom and feed line in conjunction with the above described positioning of dipoles and parasitics, provides a lightweight, readily assembled VHF- UHF-FM antenna having all elements supported parallel to each other and symmetrical about the boom axis. These elements, for practical purposes, are in the plane of the boom or, more precisely, lie in the parallel planes which are tangent to or contain the top and bottom walls of the boom. The sections of the antenna responsive to the different frequency bands are disposed in line and in series on the boom and so have a balanced well-ordered appearance in addition to providing a high performance broadband capability. What is claimed is: 1. A log periodic end fire array having an axis comprising a pair of juxtaposed spaced arially extending feed lines, a plurality of axially adjacent antenna sections adapted to receive signals in as many frequency separated bands, each section comprising a plurality of dipoles extending in directions transverse to said axis and symmetrically disposed about said axis with the dipole halves on the same side of said axis directly electrically connected to the same feed line,

the lengths and axial spacings of successive dipoles in each section decreasing in one axial direction in progressive increments of a predetermined ratio,

a plurality of transversely extending parasitic elements arranged with at least one parasitic element between adjacent dipoles for reversing the phase of feed line currents between adjacent dipoles,

the ratio of the spacing between a dipole and the adjacent parasitic element to operating wavelength for the dipole being different for corresponding axially successive dipole-parasitic element pairs whereby to compensate non-uniform impedance variations between successive dipoles and the feed line.

2. The antenna according to claim 1 in which said dipoles and parasitic elements lie in parallel planes, said feed lines being parallel to each other and lying in the plane of said dipoles.

3. A log periodic array having an axis comprising a pair of juxtaposed spaced axially extending feed lines,

a plurality of axially adjacent antenna sections adapted to receive signals in as many frequency separated bands, each section comprising a plurality of dipoles extending in directions transverse to said axis and symmetrically disposed about said axis with the dipole halves on the same side of said axis directly electrically connected to the same feed line,

the lengths and axial spacings of successive dipoles in each section decreasing in one axial direction in progressive increments of a predetermined ratio,

a plurality of transversely extending parasitic elements arranged with at least one parasitic element between adjacent dipoles,

one of said sections having two of said parasitic elements between at least one pair of adjacent dipoles, said two parasitic elements being equally spaced from one of said pair of adjacent dipoles,

the ratio of the spacing between a dipole and the adjacent parasitic element to operating wavelength for the dipole being different for corresponding axially successive dipole-parasitic element pairs whereby to compensate non-uniform impedance variations between successive dioples and the feed line.

4. The array according to claim 3 in which said feed lines comprise'the boom for the array, said dipoles and parasitic elements being supported on said boom within parallel planes tangent to the boom.

5. A log periodic array having an axis comprising a pair of juxtaposed spaced axially extending feed lines,

a plurality of axially adjacent antenna sections adapted to receive signals in as many frequency separated bands, each section comprising a plurality of dipoles extending in directions transverse to said axis and symmetrically disposed about said axis with the dipole halves on the same side of said axis directly electrically connected to the same feed line,

the lengths and axial spacings of successive dipoles in each section decreasing in one axial direction in progressive increments of a predetermined ratio,

a plurality of transversely extending parasitic elements arranged with at least one parasitic element between adjacent dipoles for reversing the phase of feed line currents between adjacent dipoles,

the ratio of the spacing between a dipole and the adjacent parasitic element to operating wavelength for the dipole being different for corresponding axially successive dipole-parasitic element pairs whereby to compensate non-uniform impedance variations between successive dipoles and the feed line,

said dipoles and parasitic elements lying in parallel planes, said feed lines being parallel to each other and lying in plane of said dipoles,

an additional antenna section comprising a pluarlity of log periodically related dipoles parallel to the dipoles of the first named sections and symmetrically disposed about said axis with dipole halves on the same side of the axis alternately connected to the same one of said feed lines.

6. The antenna according to claim in which said feed lines in said additional antenna section are in a plane perpendicular to the plane of the feed lines in said first named antenna sections.

7. A television antenna adapted -to receive signals in a plurality of frequency separated bands extending from 54 mHz. to 890 mHz., comprising a boom having an axis coincident with the antenna axis,

a plurality of antenna sections adapted to receive signals in said bands, respectively, axially spaced along said boom, each section comprising,

a plurality of parallel dipoles extending in directions transverse to said axis and disposed symmetrically of said axis,

the lengths and axial spacings of successive dipoles in each section decreasing in one axial direction in progessive increments of a predetermined ratio, and

means for electrically energizing said dipoles.

8. A television antenna adapted to receive signals in a plurality of frequency separated bands extending from 54 mHz. to 890 mHz., comprising a boom having an axis coincident with the antenna axis,

a plurality of antenna sections adapted to receive signals in said bands, respectively, axially spaced along said boom, each section comprising,

a plurality of parallel dipoles extending in directions transverse to said axis and disposed symmetrically of said axis,

the lengths and axial spacings of successive dipoles in each section decreasing in one axial direction in progressive increments of a predetermined ratio,

each of said sections responsive to signals in the range of to 900 mHz. having at least one parasitic element between adjacent dipoles for reversing the phase of the electrical energy between said adjacent dipoles, and

means for electrically energizing said dipoles.

9. The antenna according to claim 8 in which said energizing means comprises an unbalanced transmission line, said boom comprising electrically conductive members connected at one end to said transmission line.

10. The antenna according to claim 9 in said dipoles and said parasitic elements extend within parallel planes tangent to opposite sides of said boom.

References Cited UNITED STATES PATENTS Re. 25,604 6/1964 Greenberg 343-7925 2,955,289 10/1960 Winegard 343-815 3,267,479 8/1966 Smith et al. 343-7925 3,277,491 10/1966 Liu 343-815 3,321,764 5/1967 Winegard 343-7925 3,427,659 2/1969 Finneburgh et a1. 343-815 HERMAN K. SAALBACH, Primary Examiner S. CHATMON, JR., Assistant Examiner US. Cl. X.R. 343-810, 815 

